(R)-Selective ω-transaminase (ω-TA) is a key enzyme for the asymmetric reductive amination of carbonyl compounds to produce chiral amines which are essential parts of many therapeutic compounds. However, its practical industrial applications are hindered by the low catalytic efficiency and poor thermostability of naturally occurring enzymes. In this work, we report the molecular modification of (R)-selective ω-TA from Aspergillus terreus (AtTA) to allow asymmetric reductive amination of 4-hydroxy-2-butanone, producing (R)-3-amino-1-butanol. Based on substrate docking analysis, 4 residues in the substrate tunnel and binding pocket of AtTA were selected as mutation hotspots. The screening procedure was facilitated by the construction of a "small-intelligent" library and the use of thin-layer chromatography for preliminary screening. The resulting mutant AtTA-M5 exhibited a 9.6-fold higher kcat/Km value and 9.4&nbsp;°C higher [Formula see text] than that of wild-type AtTA. Furthermore, the conversion of 20 and 50&nbsp;g&nbsp;L-1 4-hydroxy-2-butanone by AtTA-M5 reached 90.8% and 79.1%, suggesting significant potential for production of (R)-3-amino-1-butanol. Under the same conditions, wild-type AtTA achieved less than 5% conversion. Moreover, the key mutation (S215P in AtTA) was validated in 7 other (R)-selective ω-TAs, indicating its general applicability in improving the catalytic efficiency of homologous (R)-selective ω-TAs.Acetate is the main by-product from microbial succinate production. In this study, we performed acetate removal by Methanosarcina barkeri 227 for succinate fermentation by Actinobacillus succinogenes 130Z. The acetoclastic methanogen M. barkeri requires similar environmental factors to A. succinogenes, and the conditions required for co-cultivation were optimized in this study gas used for anaerobicization, strain adaptation, medium composition, pH adjustment, and inoculation time points. M. barkeri 227 was adapted to acetate for 150&nbsp;days, which accelerated the acetate consumption to 9-fold (from 190 to 1726&nbsp;mmol gDW-1&nbsp;day-1). In the acetate-adapted strain, there was a noticeable increase in transcription of genes required for acetoclastic pathway-satP (acetate transporter), ackA (acetate kinase), cdhA (carbon monoxide dehydrogenase/acetyl-CoA synthase complex), and mtrH (methyl-H4STPCoM methyltransferase), which was not induced before the adaptation process. The activities of two energy-consuming steps in the pathway-acetate uptake and acetate kinase-increased about 3-fold. This acetate-adapted M. barkeri could be successfully applied to succinate fermentation culture of A. succinogenes, but only after pH adjustment following completion of fermentation. This study suggests the utility of M. barkeri as an acetate scavenger during fermentation for further steps towards genetic and process engineering.More than 100&nbsp;years have passed since the discovery of Mycobacterium tuberculosis, in 1882, as the pathogen that causes tuberculosis (TB). However, globally, TB is still one of the leading causes of death by infectious diseases. In 2018, approximately 10.0 million people were diagnosed with TB owing to the development of advanced strategies by M. tuberculosis to resist antibiotics, including the development of a dormant state. The World Health Organization (WHO) and the Sustainable Development Goals (SDGs) are dedicated to ending TB by 2030. However, the development of strategies to discover new TB drugs and new therapies is crucial for the achievement of this goal. Unfortunately, the rapid occurrence of multidrug-resistant strains of M. tuberculosis has worsened the current situation, thereby warranting prioritized discovery of new anti-TB drugs and the development of new treatment regimens in academia and the pharmaceutical industry. In this mini review, we provide a brief overview of the current research and development pipeline for new anti-TB drugs and present our perspective of TB drug innovation. The data presented herein may enable the introduction of more effective medicines and therapeutic regimens into the market.Key Points? The Updated Global New TB Drug Pipelines are briefly summarized.? Novel strategies for the discovery of new TB drugs, including novel sources, bioinformatics, and synthetic biology strategies, are discussed.? New therapeutic options, including living therapeutics and phage therapy, are proposed.Transcriptome data and gene expression analysis have a huge potential in the study of multiple relationships involving plants, pathogens, and pests, including the interactions with beneficial microorganisms such as endophytes or other functional groups. Next-generation sequencing (NGS) and other recent long-read-based sequencing approaches (i.e., nanopore and others) provide unprecedented tools allowing the fast identification of plant information processing systems, in situ and in real time, fundamental for crop management and pest regulation. Other -omics approaches such as metagenomics and metatranscriptomics allow high-resolution insights on the rhizosphere ecology. They may highlight key factors affecting belowground biodiversity or processes, modulating the expression of stress-responsive pathways. The application of miRNAs and other small RNAs is a relatively new field of application, with enormous potential for the selective activation of defense pathways. However, limitations concerning the stability of the RNA molecules and their effective delivery must be overcome.Pityriasis rubra pilaris is a&nbsp;rare papulosquamous chronic skin disease. The disease often exists for years and is difficult to treat. Not only is it clinically similar to psoriasis vulgaris, but both diseases also have a&nbsp;similar cytokine profile. The successful use of biologicals is frequently reported in case reports. Studies with large numbers of cases are lacking.This study focuses on seasonal variations of heavy metals in the soil around a coal fired thermal power plant in Udupi district, which is a densely populated town in the tropical southwest coast of India. This study, pertaining to 48 soil samples, collected during the pre-monsoon, early-monsoon, monsoon and post-monsoon seasons for one&nbsp;year, reveals that the chemistry of collected soil samples is influenced by non-pedogenic (anthropogenic) sources such as fly-ash deposition from the thermal power plant and vehicular emissions. https://www.selleckchem.com/products/d34-919.html This was concluded based on grouping of similar behaved elements through correlation-regression analysis. The distance-wise distribution of heavy metals and backward wind-trajectory analysis suggests that pre-monsoon and post-monsoonal samples are more influenced by anthropogenic activities compared to rest of the seasons. This is supported by high concentration of Zn in pre-monsoon (25.21&nbsp;mg/kg) and post-monsoon (21.32&nbsp;mg/kg) seasons compared to early-monsoon (17.05&nbsp;mg/kg) and monsoon (8.